A highly active CH4 catalyst correlated with solid oxide fuel cell anode performance

Methane catalytic abilities are considered to be an important and direct form of experimental evidence for evaluating the efficacy of mixed oxide-ion/electron conductors (MIEC) as anode materials for solid oxide fuel cells (SOFCs) with CH4 as the fuel gas. Therefore, a direct link between the quantifiable methane-conversion abilities and CH4-based SOFC electrochemical performance is urgently needed. Here, H-2-reduced Sr2ZnMoO6 (R-SZMO) as an anode example exhibits excellent catalytic abilities and tolerance to coking when using CH4 as the fuel gas, which is dominated by the formation of intrinsic anion-Frenkel defect pairs. DFT calculations reveal that the efficient electron transfer process and optimal selectivity towards CH4 conversion are both on the R-SZMO (110) surface. Therefore, applying high CH4 activity R-SZMO as the anode catalyst gives excellent anti-carbon deposition performance, high power output, and long-term stability for SOFCs with CH4 as the fuel gas.

Automated summary

Methane catalytic abilities are crucial for evaluating the effectiveness of mixed oxide-ion/electron conductors as anode materials for solid oxide fuel cells, with H-2-reduced Sr2ZnMoO6 showing excellent catalytic abilities and tolerance to coking when using CH4 as the fuel gas. Additionally, DFT calculations reveal efficient electron transfer processes and optimal selectivity towards CH4 conversion on the R-SZMO (110) surface, leading to excellent anti-carbon deposition performance, high power output, and long-term stability for CH4-based SOFCs.